Arthroscopic assessment of articular tissues is highly subjective and poorly reproducible. To ensure optimal patient care, quantitative techniques (e.g., near infrared spectroscopy (NIRS)) could substantially enhance arthroscopic diagnosis of initial signs of post-traumatic osteoarthritis (PTOA). Here, we demonstrate, for the first time, the potential of arthroscopic NIRS to simultaneously monitor progressive degeneration of cartilage and subchondral bone in vivo in Shetland ponies undergoing different experimental cartilage repair procedures. Osteochondral tissues adjacent to the repair sites were evaluated using an arthroscopic NIRS probe and significant (p < 0.05) degenerative changes were observed in the tissue properties when compared with tissues from healthy joints. Artificial neural networks (ANN) enabled reliable (ρ = 0.63–0.87, NMRSE = 8.5–17.2%, RPIQ = 1.93–3.03) estimation of articular cartilage biomechanical properties, subchondral bone plate thickness and bone mineral density (BMD), and subchondral trabecular bone thickness, bone volume fraction (BV), BMD, and structure model index (SMI) from in vitro spectral data. The trained ANNs also reliably predicted the properties of an independent in vitro test group (ρ = 0.54–0.91, NMRSE = 5.9–17.6%, RPIQ = 1.68–3.36). However, predictions based on arthroscopic NIR spectra were less reliable (ρ = 0.27–0.74, NMRSE = 14.5–24.0%, RPIQ = 1.35–1.70), possibly due to errors introduced during arthroscopic spectral acquisition. Adaptation of NIRS could address the limitations of conventional arthroscopy through quantitative assessment of lesion severity and extent, thereby enhancing detection of initial signs of PTOA. This would be of high clinical significance, for example, when conducting orthopaedic repair surgeries.
Osteoarthritis (OA) is a disabling disease associated with joint pain and restricted mobility, especially in the elderly1,2. Post-traumatic OA (PTOA), however, affects people of all ages and is initiated by joint trauma2, e.g., cartilage, meniscus, and ligament tears. These traumas conventionally require arthroscopic intervention, which is a common technique in both human and equine medicine. Mechanisms involved in the degeneration of articular cartilage have been extensively researched, and several studies3,4 have suggested changes in the subchondral bone properties to contribute to the initiation and progression of OA. In addition, subchondral bone is susceptible to morphological and compositional changes due to alterations in the stress distribution5,6; these changes can substantially influence joint functionality. Conventional arthroscopy is, however, based on qualitative visual and tactile assessment, rendering the technique subjective with suboptimal reliability7,8. Reliable evaluation of defects and the surrounding tissues is essential in choosing the optimal repair procedure and, thus, for halting the progression of PTOA9,10. This highlights the need for novel quantitative arthroscopic techniques, such as ultrasound11, optical coherence tomography (OCT12), and near infrared spectroscopy (NIRS13).
NIRS is a non-destructive optical technique in which the sample is irradiated with light, and the scattered and reflected light is collected. The technique enables rapid evaluation of tissues in vivo and eliminates the need for invasive, destructive, and slow chemical analysis14. NIRS enables swift assessment of cartilage biomechanical properties13,15,16,17,18 and composition13, as well as subchondral bone structure19. The spectral range between 0.4 and 2.5 µm enables assessment of the tissue at various depths due to the wavelength-dependent penetration depth20. The shorter wavelengths penetrate through the cartilage matrix into the subchondral and trabecular bone21, whereas longer wavelengths (closer to the mid infrared region) are restricted to the superficial layer of cartilage20. While there are several in vitro studies on the application of NIRS for cartilage assessment13,15,16,17,18,21,22, only a few have investigated the potential of this optical technique in vivo23,24,25,26,27. Furthermore, in these in vivo studies, cartilage condition was only evaluated using simple and poorly effective analytical approaches, such as determining the ratio of spectral peaks. Robust and effective analytical techniques, such as neural networks, could enable more accurate and reliable estimation of cartilage properties from the near infrared (NIR) spectral data.
Advances in multivariate analysis techniques and the increase in available computational resources have enabled accurate modelling of the relationships between complex NIR spectral data and reference parameters, such as cartilage biomechanical properties. Partial least squares regression (PLSR) is currently the most common technique in chemometrics for analysis of NIR spectral data28. However, artificial neural networks (ANN) combined with variable selection methods have recently been introduced for analysis of cartilage spectral data22,29,30 and have shown potential for evaluation of tissue properties.
We hypothesize that arthroscopic NIRS enables reliable simultaneous evaluation of articular cartilage and subchondral bone in vivo via adaptation of ANN. To test this hypothesis, arthroscopic and in vitro NIRS measurements were conducted on tissue surrounding experimental cartilage repair sites in equine joints at the 12-month end-point and compared with unaffected tissue harvested from matching sites in healthy control ponies. As references, articular cartilage biomechanical properties and subchondral bone microstructure and density were determined via indentation testing and computed tomography, respectively. To investigate the relationship between the spectral data and reference parameters, ANN with forward variable selection technique was adapted.
Two cylindrical (d = 9 mm) chondral lesions were surgically created on the medial femoral ridges of both femoropatellar joints of Shetland ponies (N = 7, 6 females and 1 male, Age = 8.8 ± 3.5 years, total of 28 lesions). Each lesion was treated by filling it with Gelatin Methacryl (GelMA) hydrogel (3 varieties) or fibrin glue31. The repair procedure (fibrin glue, GelMA cap, GelMA, or reinforced GelMA) was randomized (proximal or distal lesion site and left or right knee) for each defect. A mixture of allogeneic mesenchymal stem cells (MSCs) and chondrons (80/20% ratio) at different concentrations was implanted in each defect. In the fibrin glue group, a low cell concentration (2 million cells/ml) was used, whereas the GelMA cap group had 1 million cells in a small volume of GelMA on the bottom of the defect, covered by a layer of cell free GelMA. In the last two groups, a high concentration (20 million cells/ml) was implanted in GelMA gel, and in the reinforced GelMA group, GelMA was reinforced with a 3D printed scaffold (melt electrospun polycarpolactone mesh)32.
After 12 months, the ponies were sacrificed and the osteochondral defects, together with the surrounding tissues, were examined via conventional and NIRS arthroscopes. Subsequently, osteochondral blocks were extracted for further analysis. As control, a similar osteochondral block was extracted from both femoropatellar joints of healthy ponies (Ncontrol = 3, Age = 10.3 ± 4.7 years), ensuring an overall representative sample population. The animal studies were approved by the Ethics Committee of Utrecht University for Animal Experiments in compliance with the Institutional Guidelines on the Use of Laboratory Animals and carried out in a surgical theatre at the Department of Equine Sciences, Utrecht University, The Netherlands (Permission DEC 2014.III.11.098). The control ponies were acquired from a slaughterhouse in Utrecht, The Netherlands.
Arthroscopic near infrared spectroscopy
Near infrared (NIR) spectral measurements (Nponies = 7, Nper joint = 12, Ntotal = 164, 4 locations arthroscopically unreachable) were acquired arthroscopically in vivo by an experienced board-certified equine surgeon (>500 arthroscopies, Diplomate European College of Veterinary Surgeons) at the 12-month time-point immediately upon sacrifice. The arthroscopies were performed by utilizing a traditional arthroscope (4 mm, 30° inclination, Synergy HD3, Arthrex, Naples, FL, USA) as a monitoring tool and a novel, robust, and reusable arthroscopic NIRS fibre probe as a measurement tool (Fig. 1a). Twelve locations surrounding cartilage repair sites were measured (Fig. 1b) by orientating the fibre probe in perpendicular contact with cartilage surface. At each measurement point, 15 spectra were recorded, each being the average of ten successive spectra; the total duration of data acquisition was 2.4 seconds per measurement location. Arthroscopic images were recorded with a conventional arthroscope during the operation to enable reliable location tracking. Ringer’s solution (Fresenius, Bad Homburg v.d.H., Germany) containing sodium chloride (8.6 g/L), potassium chloride (0.3 g/L), and calcium chloride (0.33 g/L) was used for joint distension. Following the measurements, osteochondral samples were extracted after removing the skin and overlying tissues of the joint (Fig. 1b). The samples were frozen (−20 °C) until required for laboratory NIRS, biomechanical, and computed tomography (CT) measurements.
In vitro near infrared spectroscopy
The in vitro NIRS measurements (Nponies = 10, Nper joint = 12, Ntotal = 236; same 4 locations excluded as during arthroscopy) were acquired in similar conditions as in arthroscopy, i.e., hardware, immersion solution, and temperature, apart from using the conventional arthroscope for navigation. At each measurement point, three successive spectra were acquired, each consisting of 10 co-added scans.
The NIRS system consisted of spectrometers (AvaSpec-ULS2048L, λ = 0.35–1.1 µm, resolution = 0.6 nm and AvaSpec-NIR256-2.5-HSC, λ = 1.0–2.5 µm, resolution = 6.4 nm, Avantes BV, Apeldoorn, The Netherlands), a light source (AvaLight-HAL-(S)-Mini, λ = 0.36–2.5 µm, Avantes BV), and a custom arthroscopic fibre probe (Avantes BV). The reusable stainless-steel fibre probe (d = 3.25 mm) is sterilisable in an autoclave at 121 °C and its tip resembles the shape of a traditional arthroscopic hook. The probe tip window (d = 2 mm) contains 114 optical fibres (d = 100 µm), with 100 fibres emitting and 14 fibres (7 + 7) collecting light to the spectrometers. Avasoft software (version 8.7.0, Avantes BV) was used for spectral acquisition.
A 3rd order Savitzky-Golay filter was applied for smoothing of spectral data separately for the two spectrometers due to differences in their wavelength resolution. For cartilage and subchondral bone properties, the smoothing points were 25 and 13, and 45 and 13 points, respectively. The spectral region 1.9–2.5 µm was discarded from the analyses due to spectral saturation caused by high absorption of water.
In the arthroscopic NIRS measurements, interference from the light source of the conventional arthroscope was observed in the visible spectral region (λ ≈ 0.42–0.75 µm, Fig. 1d). Therefore, this region was applied only as an indicator for probe orientation and not used in the modelling. For arthroscopic NIRS, sufficient contact of the probe with cartilage surface is essential, as the irrigation fluid (i.e., saline) is an effective absorber of NIR light. To evaluate contact between the probe and cartilage surface, the area between a two-point linear fit and the measured spectrum (in a spectral region of 0.42–0.75 µm) was calculated (Fig. 1c). Four measurement locations were excluded due to high contribution from the arthroscope light source. Additionally, seven spectra (with the largest area between a linear fit and measured spectrum) out of the fifteen measured spectra from all measurement locations were excluded. Coefficient of variation was determined between the arthroscopic and in vitro spectra in spectral region 0.75–1.9 µm (3.7 ± 1.9%)17.
Optical coherence tomography
After in vitro NIRS measurements, the measurement locations were marked with a felt tip pen. These points were imaged with OCT (λ = 1305 ± 55 nm, axial resolution < 20 µm, lateral resolution 25–60 µm; Ilumien PCI Optimization System, St. Jude Medical, St. Paul, MN, USA) by aligning a catheter (C7 Dragonfly, St. Jude Medical) over the measurement points (Fig. 1b) and performing a pullback imaging, thus imaging the NIRS measurement locations and the surrounding tissue (Fig. 2a–c). The samples were submerged in phosphate-buffered saline (PBS) during the imaging. Cartilage thickness was then determined from the OCT images of each location for biomechanical measurements.
Biomechanical properties of cartilage surrounding the repairs (Nponies = 10, Nper joint = 12, Ntotal = 236) were determined via indentation testing. The samples were glued on a custom-made sample holder, which was mounted on a goniometer (Model #55-841, Edmund Optics Inc., Barrington, NJ, USA) to align the cartilage surface perpendicular with the face of a plane-ended non-porous cylindrical indenter (d = 0.53 mm). Measurements were performed with the samples submerged in PBS. The indentation system consisted of a 250 g load cell (accuracy ± 0.25%, Model 31, Honeywell Sensotec Sensors, Columbus, OH, USA) and an actuator (displacement resolution 0.1 µm, PM500-1 A, Newport, Irvine, CA, USA).
First, the indenter was driven into initial contact with the sample. The contact was then ensured by indenting the sample five times using 2% strain. The measurement protocol consisted of four stress-relaxation steps (each of 5% strain) with a ramp velocity of 100%/s and a relaxation time of 600 seconds between the steps, followed by dynamic sinusoidal loading (f = 1.0 Hz) with a strain amplitude of 1%. The equilibrium modulus (Eeq) was determined from the linear region of the stress-relaxation curve by assuming Poisson’s ratio of ν = 0.1, whereas the dynamic modulus (Edyn) was calculated as a ratio of the stress and strain amplitudes of the sinusoidal loading assuming a Poisson’s ratio of ν = 0.533,34.
Computed tomography and segmentation
Samples were imaged while submerged in PBS with a micro-CT scanner (Skyscan 1172, Skyscan, Kontich, Belgium) to determine subchondral bone plate and trabecular bone bone volume fraction (BV), bone mineral density (BMD), bone thickness, and trabecular bone structure model index (SMI). The samples were imaged using an isotropic voxel size of 12.15 × 12.15 × 12.15 µm3 and 100 kV tube voltage, along with hydroxyapatite phantoms (500, 1000, and 1250 mg/cm3). To ensure reliable location tracking for the segmentation, plastic cubes of approximately 8 mm3 were set on the NIRS measurement locations (Fig. 1b). From each measurement location, a cylindrical (diameter = 4.0 mm, height = 5.0 mm) region of interest (ROI) was virtually extracted, and the subchondral plate and trabecular bone were segmented (Fig. 2d–f). The extraction, segmentation, and analysis of bone properties were performed with DataViewer (Skyscan) and CTAn (Skyscan) programs. A global segmentation threshold (BMD = 0.46 g/cm3) was determined by comparing the binarized and original grayscale images.
Artificial neural network
The relationship between NIR spectra and reference parameters was investigated using ANN. The ponies were divided into calibration (60%, N = 4 and Ncontrol = 2, 142 spectra), validation (30%, N = 2 and Ncontrol = 1, 70 spectra), and test (10%, N = 1, 24 spectra) groups. For each reference parameter, in vitro models with spectral regions 0.75–1.90 µm (Model 2) and 0.40–1.90 µm (Model 3) were developed based on in vitro NIR spectra and optimized by determining the most reliable wavelengths via the forward variable selection technique22,29. The optimal model was chosen based on the smallest root mean square error (RMSE) of the test group. Additionally, a model (0.75–1.90 µm, Model 1) was developed in which the most reliable wavelengths were determined by evaluating RMSE values of two sets: the test group and the arthroscopic measurements. For each location of the arthroscopic measurements, the final predicted value was resolved as an average of non-negative predicted values. During ANN modelling, the Levenberg-Marquardt backpropagation algorithm was used, while hyperbolic tangent and linear activation functions were employed in the hidden and output layers, respectively. To avoid overfitting, model training was halted after the validation error did not decrease in six successive iterations. The neural network architecture was limited to a maximum of eight neurons in the hidden layer and the analysis was performed in MATLAB (Matlab R2017b, MathWorks Inc., Natick, MA, USA) using the neural network toolbox (Version 11.0). To further evaluate model performance and reliability, the normalized RMSE (NRMSE) and ratio of performance to inter-quartile range (RPIQ)35 were calculated for in vitro training set (calibration and validation), independent test group, and arthroscopic predictions separately. The NRMSE is determined as RMSE relative to the reference parameter range, whereas RPIQ is determined as
where IQR is the inter-quartile range of the measured data. The RPIQ was chosen due its suitability for non-normally distributed data35 and the threshold for reliable models was set to RPIQ ≥ 2, based on previous studies36,37.
Reference properties had a non-normal distribution (Shapiro-Wilk normality test, p < 0.0003) and, thus, non-parametric tests were employed in statistical analysis. Statistical significance of differences in tissue properties between cartilage repair and control ponies was investigated by using the Mann-Whitney U test in SPSS (Version 23, SPSS Inc., IBM Company, Armonk, NY, USA); p < 0.05 was set as the limit for statistical significance. Two-tailed Spearman (ρ) correlation coefficients were determined between the measured and NIRS predicted reference parameter values.
Data of the current study is available from the corresponding author on reasonable request.
Significant differences (p < 0.05) between the cartilage repair and control groups were observed in values of measured cartilage biomechanical properties (adjacent to the repair site), subchondral bone plate BV, and BMD (Figs. 2, 3, and Supplementary Figs. S1–5). Nevertheless, no significant differences (p = 0.16–0.93) were observed in cartilage thickness between the groups (Supplementary Fig. S1). The optimal predictive models (Model 1, ρCalibration&Validation = 0.63–0.87, RPIQCalibration&Validation = 1.93–3.03) reliably predicted the tissue properties (ρTest = 0.54–0.91, RPIQTest = 1.68–3.36) of the independent test group apart from subchondral bone BV (ρCalibration&Validation = 0.69, RPIQCalibration&Validation = 1.34, ρTest = 0.58, RPIQTest = 1.30) from in vitro spectral data (Table 1) for the four locations at different distances from the repaired lesion (Fig. 3), thus accurately differentiating between healthy and post-traumatic tissue. Furthermore, cartilage models (average RPIQCalibration&Validation = 2.76, RPIQTest = 3.26) were superior to subchondral bone plate (average RPIQCalibration&Validation = 1.99, RPIQTest = 1.95) and trabecular bone models (average RPIQCalibration&Validation = 2.09, RPIQTest = 2.27). In addition, arthroscopic predictions with optimal predictive models (Model 1) also enabled differentiation between healthy and post-traumatic tissue (Fig. 3). Although, the prediction performance (ρ = 0.27–0.74, RPIQ = 0.81–1.70) was inferior when compared to in vitro predictions, possibly due to errors (e.g., non-perfect contact of the probe and cartilage surface) introduced during arthroscopic spectral acquisition.
For the locations with only arthroscopic measurements (Methods: Fig. 1b, red dots), the trends of predicted values (Model 1) were consistent with those of measured values at other locations (Supplementary Figs. S1–5). Additionally, predictive models based on in vitro spectral data from the 0.75 to 1.9 µm region (Model 2) were optimal for estimating cartilage and subchondral bone plate properties, whereas models with a wider spectral region (0.4–1.9 µm, Model 3) incorporating the visible region were optimal for predicting subchondral trabecular bone properties (Table 1).
Currently, no quantitative arthroscopic tools are available for evaluation of cartilage and subchondral bone and thus orthopaedic surgeons have to manage with subjective visual scoring of injury severity and tissue probing with a metallic hook7. Although several arthroscopic instruments for biomechanical assessment of cartilage (e.g., Artscan38) have been introduced, several practical issues (e.g., poor inter-observer reliability) have limited their usage during routine arthroscopies38. In addition, ultrasound and OCT imaging have been suggested, but these have not yet gained wide acceptance for arthroscopic evaluation of cartilage11,12. For arthroscopic evaluation of subchondral bone, there are currently no clinical tools available; nevertheless, arthroscopic ultrasound imaging has been shown to provide information on the subchondral bone39. CT and MRI are widely used for diagnostics of joint injuries, but these techniques cannot be utilized during arthroscopic repair surgery. As a result, the presently introduced NIRS probe could be used to accurately localize cartilage and bone defects, as well as the spread of tissue degeneration from an injury during arthroscopy, therefore potentially leading to better outcome of the tissue repair. Predictive models based on ANN provided accurate estimates of reference parameters for an independent in vitro test group. Although predictions based on spectra collected during in vivo arthroscopies had slightly higher errors (i.e., weaker performance), they were able to discriminate between healthy and post-traumatic tissue. These findings suggest that NIRS is a promising technique for in vivo assessment of articular cartilage and subchondral bone properties.
Near infrared spectroscopy has been applied previously in human arthroscopies by Spahn et al. and Hofmann et al. to evaluate the condition of cartilage23,24,25,26,27. However, no study has applied NIRS for evaluation of subchondral bone properties in vivo, or for simultaneous assessment of cartilage and subchondral bone integrity, or for prediction of tissue properties based on in vivo NIRS arthroscopy. In the aforementioned studies, a spectral region of 0.9–1.7 µm was utilized, whereas a wider region of 0.4–1.9 µm was utilized in the present study. Furthermore, the previous studies applied a simple univariate approach based on the ratio of spectral peaks for assessments of cartilage condition25,27, while a more advanced analytical approach based on ANN was adopted in this study.
The spectral region 0.75–1.9 µm was optimal for prediction of cartilage biomechanical and subchondral bone plate properties (i.e., subchondral plate thickness, BV, and BMD), while models that also incorporated the visible region (0.4–0.75 µm) enhanced the reliability of predicting subchondral trabecular bone properties (i.e., trabecular thickness, BV, BMD, and SMI). This is due to better penetration of visible light through cartilage and into subchondral bone20. Nevertheless, the errors of arthroscopic predictions were higher for subchondral bone plate and trabecular bone properties compared to cartilage biomechanical properties, possibly due to contributions from the overlying cartilage matrix. Furthermore, since probe contact with the cartilage surface affects the transmission of light into the tissue, this is possibly the reason for the weaker prediction of bone properties based on arthroscopic spectral measurements. Detailed understanding of wavelength-dependent light penetration would provide insight that enables quantification of the effect of the overlying cartilage in future studies.
The overall errors of prediction based on spectral data collected during arthroscopies were higher compared to those based on in vitro measurements. This is probably due to the difficulty in ensuring perfect probe contact with cartilage surface during arthroscopic spectral acquisition due to the geometrical constraints in the live situation. In the analysis, predictions based on the best 8 arthroscopic spectra (out of 15 recorded for each measurement location) resulted in the most reliable predictions; however, these spectra were not necessarily obtained through perfect probe contact. To enhance the identification of optimal spectra for each measurement location, additional indicators or classification algorithms, e.g., support vector machines and decision trees, could be utilized. However, this was beyond the scope of the current investigation. Additionally, for future studies the pressure between the arthroscopic NIR probe and cartilage surface should be quantitatively measured in order to minimize its effect on the resulting NIR spectra and consequently the prediction accuracy40,41.
The gold standard multivariate technique used in multiple applications (e.g., determining soil properties) is PLSR; however, ANN has in many occasions outperformed PLSR42,43. Furthermore, ANN modelling does not require extensive preprocessing22, whereas PLSR often requires scatter correction and derivative pre-processing for optimal performance. Generally, ANNs, in particular deep neural networks (≥2 hidden layers), are considered to require more data. However, only shallow neural networks (with single hidden layer) were utilized in this study. Therefore, similar estimates of minimum number of observations can be applied for shallow ANN models as multivariate models, such as PLSR and multiple linear regression (MLR). Consequently, we deem over hundred observations to be sufficient with more being always better. In addition, roughly 200 observations were recommended by Bujang et al. when applying MLR44. Although the number of spectra (N = 24) in the independent test set was low, this test provides an unbiased evaluation of model performance. Furthermore, the relatively small prediction errors ensured that the models were well-generalized for new samples. As expected, the forward variable selection technique improved the performance and robustness of the models by reducing the number of wavelengths; this is consistent with our previous study22. The prediction errors in cartilage biomechanical properties based on arthroscopic spectra were substantially lower with the variable selection technique employed in the present study compared to the genetic algorithm approach applied in our previous study30.
The correlations demonstrated by the models arise from overtone vibrations of chemical bonds in the main constituents of articular cartilage and subchondral bone, i.e., water, proteoglycans, collagen (types I and II), and hydroxyapatite. The most common bonds in these tissue constituents are OH, SH, NH, CH, and PO445,46. Water is the most abundant constituent (up to 80%) in cartilage45 and thus the OH bond has a substantial influence on the spectral response of cartilage. The main peaks associated with the tissue water content appear between 0.95–1.10 µm, 1.40–1.55 µm, and 1.80–2.00 µm due to second overtone OH stretching, first overtone OH stretching, and second overtone OH bending vibrations, respectively47. The spectral regions 0.95–1.10 µm and 1.40–1.55 µm also include contributions from the second and first overtones of NH stretching vibrations47, respectively. In addition, overtones of CH stretching vibrations can be observed at spectral regions 0.85–0.95 µm, 1.10–1.25 µm, and 1.65–1.80 µm47. Spectral data from regions of stronger vibrations (first overtones) contribute more to model performance as observed from the histograms of selected wavelengths (Fig. 2g–i). The spectral region associated with the first overtone OH stretching vibration (1.40–1.55 µm) contributes substantially to the models, particularly for articular cartilage and subchondral bone plate parameters. For subchondral trabecular bone, the emphasis shifts towards the lower wavelengths (1.05–1.2 µm) due to better penetration depth of the light20.
The relationship between NIR spectra and cartilage biomechanical properties has been previously investigated in vitro with univariate15,18 and multivariate13,16,17 analysis (i.e., PLSR). These studies utilized relatively narrow spectral regions with moderate and good correlations, whereas in this study a wider region was utilized along with ANN combined with a variable selection technique. Afara et al. investigated subchondral bone properties with a similar spectral region in a rat model with promising results19. However, cartilage in a rat knee joint is substantially thinner than in human and equine knee joints48,49. Thus, the findings in the present study indicate that NIRS is a feasible technique for assessment of subchondral bone properties, even through thicker human and equine cartilage. Nevertheless, additional studies are required to confirm the validity of the NIRS technique in human patients.
No statistically significant difference was observed in cartilage thickness between control ponies and ponies with repaired cartilage defects. However, significant variation in cartilage biomechanical properties was observed between the groups. In PTOA, cartilage surrounding the site of a defect experiences higher strains6, therefore altering the tissue’s biomechanical competence and possibly leading to remodelling of the subchondral bone50. For subchondral plate properties, statistically significant differences were observed in values of BV and BMD between the groups, which is consistent with current knowledge on early-stage subchondral bone changes in OA50,51.
A possible limitation of this study is the potential effect of dependency as arthroscopic and in vitro measurements were conducted on the same ponies (the experimental group); however, this enabled comparison between the in vitro and in vivo environments, and provided valuable information for further development of in vivo NIRS applications. An additional limitation is that the arthroscopic spectra were found to include contributions from the conventional arthroscope light source, thereby limiting the useful spectral range to the NIR region (0.75–1.90 µm) because of interference in the visible spectral region.
Near infrared spectroscopy is a promising quantitative technique for simultaneous arthroscopic assessment of cartilage biomechanical properties and subchondral bone structure and density. This technique could substantially enhance assessment of the clinical status of joints by enabling quantitative detection of initial signs of PTOA around chondral lesions. This would be of high clinical significance, e.g., when conducting articular repair surgery.
Buckwalter, J. A. & Martin, J. A. Osteoarthritis. Adv. Drug Deliv. Rev. 58, 150–67 (2006).
Buckwalter, J. A. & Brown, T. D. Joint injury, repair, and remodeling: roles in post-traumatic osteoarthritis. Clin. Orthop. Relat. Res. 7–16 (2004).
Radin, E. L., Paul, I. L. & Tolkoff, M. J. Subchondral bone changes in patients with early degenerative joint disease. Arthritis Rheum. 13, 400–405 (1970).
Radin, E. L. & Rose, R. M. Role of Subchondral Bone in the Initiation and Progression of Cartilage Damage. Clin. Orthop. Relat. Res. 34–40 (1986).
Madry, H., van Dijk, C. N. & Mueller-Gerbl, M. The basic science of the subchondral bone. Knee Surgery, Sport. Traumatol. Arthrosc. 18, 419–433 (2010).
Venäläinen, M. S. et al. Quantitative Evaluation of the Mechanical Risks Caused by Focal Cartilage Defects in the Knee. Sci. Rep. 6, 37538 (2016).
Spahn, G., Klinger, H. M. & Hofmann, G. O. How valid is the arthroscopic diagnosis of cartilage lesions? Results of an opinion survey among highly experienced arthroscopic surgeons. Arch. Orthop. Trauma Surg. 129, 1117–1121 (2009).
Brismar, B. H., Wredmark, T., Movin, T., Leandersson, J. & Svensson, O. Observer reliability in the arthroscopic classification of osteoarthritis of the knee. J. Bone Joint Surg. Br. 84, 42–47 (2002).
Favero, M., Ramonda, R., Goldring, M. B., Goldring, S. R. & Punzi, L. Early knee osteoarthritis. RMD open 1, e000062 (2015).
Chu, C. R., Williams, A. A., Coyle, C. H. & Bowers, M. E. Early diagnosis to enable early treatment of pre-osteoarthritis. Arthritis Res. Ther. 14, 212 (2012).
Virén, T. et al. Minimally invasive ultrasound method for intra-articular diagnostics of cartilage degeneration. Ultrasound Med. Biol. 35, 1546–54 (2009).
Li, X. et al. High-resolution optical coherence tomographic imaging of osteoarthritic cartilage during open knee surgery. Arthritis Res. Ther. 7, 318–323 (2005).
Afara, I. O., Hauta-Kasari, M., Jurvelin, J. S., Oloyede, A. & Töyräs, J. Optical absorption spectra of human articular cartilage correlate with biomechanical properties, histological score and biochemical composition. Physiol. Meas. 36, 1913–1928 (2015).
Rolfe, P. In Vivo Near-Infrared Spectroscopy. Annu. Rev. Biomed. Eng. 2, 715–754 (2000).
Marticke, J. K. et al. How do visual, spectroscopic and biomechanical changes of cartilage correlate in osteoarthritic knee joints? Clin. Biomech. (Bristol, Avon) 25, 332–340 (2010).
Stumpfe, S. T. et al. Is there a correlation between biophotonical, biochemical, histological, and visual changes in the cartilage of osteoarthritic knee-joints? Muscles. Ligaments Tendons J. 3, 157–65 (2013).
Sarin, J. K. et al. Near Infrared Spectroscopic Mapping of Functional Properties of Equine Articular Cartilage. Ann. Biomed. Eng. 44, 3335–3345 (2016).
Hanifi, A. et al. Near infrared spectroscopic assessment of developing engineered tissues: correlations with compositional and mechanical properties. Analyst 142, 1320–1332 (2017).
Afara, I. O., Prasadam, I., Crawford, R., Xiao, Y. & Oloyede, A. Near infrared (NIR) absorption spectra correlates with subchondral bone micro-CT parameters in osteoarthritic rat models. Bone 53, 350–7 (2013).
Padalkar, M. V. & Pleshko, N. Wavelength-dependent penetration depth of near infrared radiation into cartilage. Analyst 140, 2093–100 (2015).
McGoverin, C. M., Lewis, K., Yang, X., Bostrom, M. P. G. & Pleshko, N. The Contribution of Bone and Cartilage to the Near-Infrared Spectrum of Osteochondral Tissue. Appl. Spectrosc. 68, 1168–1175 (2014).
Sarin, J. K. et al. Combination of optical coherence tomography and near infrared spectroscopy enhances determination of articular cartilage composition and structure. Sci. Rep. 7, 10586 (2017).
Spahn, G. et al. Evaluation of cartilage defects with near-infrared spectroscopy (NIR): an ex vivo study. Med. Eng. Phys. 30, 285–92 (2008).
Spahn, G. et al. Near-infrared spectroscopy for arthroscopic evaluation of cartilage lesions: results of a blinded, prospective, interobserver study. Am. J. Sports Med. 38, 2516–21 (2010).
Spahn, G., Felmet, G. & Hofmann, G. O. Traumatic and degenerative cartilage lesions: arthroscopic differentiation using near-infrared spectroscopy (NIRS). Arch. Orthop. Trauma Surg. 133, 997–1002 (2013).
Spahn, G. et al. The frequency of cartilage lesions in non-injured knees with symptomatic meniscus tears: results from an arthroscopic and NIR- (near-infrared) spectroscopic investigation. Arch. Orthop. Trauma Surg. 137, 837–844 (2017).
Hofmann, G. O. et al. Detection and evaluation of initial cartilage pathology in man: A comparison between MRT, arthroscopy and near-infrared spectroscopy (NIR) in their relation to initial knee pain. Pathophysiology 17, 1–8 (2010).
Wold, S., Sjöström, M. & Eriksson, L. PLS-regression: a basic tool of chemometrics. Chemom. Intell. Lab. Syst. 58, 109–130 (2001).
May, R., Dandy, G. & Maier, H. Review of Input Variable Selection Methods for Artificial Neural Networks. In Artificial Neural Networks - Methodological Advances and Biomedical Applications (InTech), https://doi.org/10.5772/16004 (2011).
Sarin, J. K. et al. Spectroscopic Evaluation of Post-Traumatic Osteoarthritis in Shetland Ponies. In Biophotonics Congress: Biomedical Optics Congress 2018 (Microscopy/Translational/Brain/OTS) OTu4D.5 (OSA), https://doi.org/10.1364/OTS.2018.OTu4D.5 (2018).
Mancini, I. A. et al. Objective gait analysis as a tool to improve longitudinal monitoring of long-term large animal studies into cartilage repair. In 13th World Congress of ICRS, Sorrento, Italy. (2016).
Visser, J. et al. Reinforcement of hydrogels using three-dimensionally printed microfibres. Nat. Commun. 6, 6933 (2015).
Hayes, W. C., Keer, L. M., Herrmann, G. & Mockros, L. F. A mathematical analysis for indentation tests of articular cartilage. J. Biomech. 5, 541–551 (1972).
Danso, E. K. et al. Characterization of site-specific biomechanical properties of human meniscus—Importance of collagen and fluid on mechanical nonlinearities. J. Biomech. 48, 1499–1507 (2015).
Bellon-Maurel, V., Fernandez-Ahumada, E., Palagos, B., Roger, J.-M. & McBratney, A. Critical review of chemometric indicators commonly used for assessing the quality of the prediction of soil attributes by NIR spectroscopy. TrAC Trends Anal. Chem. 29, 1073–1081 (2010).
Peng, Y. et al. Modeling soil organic carbon at regional scale by combining multi-spectral images with laboratory spectra. PLoS One 10, e0142295 (2015).
Jia, X. et al. Organic carbon prediction in soil cores using VNIR and MIR techniques in an alpine landscape. Sci. Rep. 7, 2144 (2017).
Timonen, M. A. et al. Technical and practical improvements in arthroscopic indentation technique for diagnostics of articular cartilage softening. J. Med. Eng. Technol. 35, 40–6 (2011).
Liukkonen, J. et al. Arthroscopic ultrasound technique for simultaneous quantitative assessment of articular cartilage and subchondral bone: an in vitro and in vivo feasibility study. Ultrasound Med. Biol. 39, 1460–1468 (2013).
Cugmas, B., Bregar, M., Bürmen, M., Pernuš, F. & Likar, B. Impact of contact pressure–induced spectral changes on soft-tissue classification in diffuse reflectance spectroscopy: problems and solutions. J. Biomed. Opt. 19, 37002 (2014).
Horbert, V. et al. Comparison of Near-Infrared Spectroscopy with Needle Indentation and Histology for the Determination of Cartilage Thickness in the Large Animal Model Sheep. Cartilage 1947603517731851, https://doi.org/10.1177/1947603517731851 (2017).
Goldshleger, N., Chudnovsky, A. & Ben-Dor, E. Using Reflectance Spectroscopy and Artificial Neural Network to Assess Water Infiltration Rate into the Soil Profile. Appl. Environ. Soil Sci. 2012, 1–9 (2012).
Ni, Y., Zhang, G. & Kokot, S. Simultaneous spectrophotometric determination of maltol, ethyl maltol, vanillin and ethyl vanillin in foods by multivariate calibration and artificial neural networks. Food Chem. 89, 465–473 (2005).
Bujang, M. A., Sa’at, N. & Sidik, T. M. I. T. A. B. Determination of minimum sample size requirement for multiple linear regression and analysis of covariance based on experimental and non-experimental studies. Epidemiol. Biostat. Public Heal. 14, e12117-1–e12117-9 (2017).
Buckwalter, J. A. & Mankin, H. J. Articular cartilage: tissue design and chondrocyte-matrix interactions. Instr. Course Lect. 47, 477–86 (1998).
Buckwalter, J. A., Glimcher, M. J., Cooper, R. R. & Recker, R. Bone biology. I: Structure, blood supply, cells, matrix, and mineralization. Instr. Course Lect. 45, 371–86 (1996).
Burns, D. A. & Ciurczak, E. W. Handbook of near-infrared analysis, 3rd ed. Analytical and Bioanalytical Chemistry 393, 1387–1389 (2009).
Malda, J. et al. Comparative study of depth-dependent characteristics of equine and human osteochondral tissue from the medial and lateral femoral condyles. Osteoarthritis Cartilage 20, 1147–51 (2012).
Malda, J. et al. Of Mice, Men and Elephants: The Relation between Articular Cartilage Thickness and Body Mass. PLoS One 8, e57683 (2013).
Heijink, A. et al. Biomechanical considerations in the pathogenesis of osteoarthritis of the knee. Knee Surg. Sports Traumatol. Arthrosc. 20, 423–35 (2012).
Intema, F. et al. In early OA, thinning of the subchondral plate is directly related to cartilage damage: Results from a canine ACLT-meniscectomy model. Osteoarthr. Cartil. 18, 691–698 (2010).
Doctoral Programme in Science, Technology and Computing (SCITECO) of University of Eastern Finland, Kuopio University Hospital (VTR projects 5041750 and 5041744, PY210 Clinical Neurophysiology), the Academy of Finland (project 267551), Orion Research Foundation sr, and Finnish foundation of technology promotion financially supported this study. The research leading to these results has received funding from the European Community’s Seventh Framework Programme (FP7/2007–2013) under grant agreement 309962 (HydroZONES), the European Research Council under grant agreement 647426 (3D-JOINT), and the Dutch Arthritis Foundation (LLP-12 and LLP-22). Finnilä, M. and Malo, M. are acknowledged for the guidance in the CT acquisition and segmentation.
The authors declare no competing interests.
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Sarin, J.K., te Moller, N.C.R., Mancini, I.A.D. et al. Arthroscopic near infrared spectroscopy enables simultaneous quantitative evaluation of articular cartilage and subchondral bone in vivo. Sci Rep 8, 13409 (2018). https://doi.org/10.1038/s41598-018-31670-5
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